Mayank Agrawal1, Horace J Spencer, Fred H Faas. 1. Department of Internal Medicine, University of Arkansas for Medical Sciences and Central Arkansas Veterans Healthcare System, 4301 W Markham Street, Little Rock, AR 72205, USA. magrawal@uams.edu
Abstract
BACKGROUND: Low-density lipoprotein cholesterol (LDL-C) has been clearly associated with the risk of developing coronary heart disease. The best and most convenient method for determining LDL-C has come under increased scrutiny in recent years. We present comparisons of the Friedewald calculated LDL-C (C-LDL-C) and direct LDL-C (D-LDL-C) using 3 different homogenous assays. This highlights differences between the 2 methods of LDL-C measurement and how this affects the classification of samples into different LDL-C treatment goals as determined by the National Cholesterol Education Program Adult Treatment Panel III guidelines thus potentially affecting treatment strategies. METHODS: Lipid profiles of a total of 2208 clinic patients were retrieved from the Central Arkansas VA Healthcare System clinical laboratory database. Samples studied were of 1-week period during the 3 periods studied: 2000 (period 1), 2002 (period 2), and 2005 (period 3). Different homogenous assays for D-LDL-C measurement were used for each of the 3 periods. RESULTS: There is a fundamental disagreement between D-LDL-C and C-LDL-C, although Pearson correlation coefficients are 0.93, 0.97, and 0.98 for periods 1, 2, and 3, respectively. Using the model for period 1, when C-LDL-C is 70 mg/dL, the predicted D-LDL-C is 95 mg/dL (36% higher). The differences between C-LDL-C and predicted D-LDL-C progressively decrease at higher LDL-C cut points. In the assay used in period 3, there are 290 samples with D-LDL-C values between 100 and 130 mg/dL. Of these, only 182 samples show agreement with C-LDL-C values, whereas 90 samples with a D-LDL-C in the 100- to 130-mg/dL range are in the 70- to 100-mg/dL range using the C-LDL-C assay. Although the κ statistics suggests the LDL-C measures have relatively high levels of agreement, the significant generalized McNemar tests (P < 0.01) provide additional evidence of disagreement between C-LDL-C and D-LDL-C during all the 3 periods. CONCLUSIONS: Our results highlight D-LDL-C measurements using 3 different assays during 3 different periods. In all assays, there is a substantial lack of agreement between D-LDL-C and C-LDL-C, which, in most cases, resulted in higher D-LDL-C values than C-LDL-C. This leads to clinically significant misclassification of patient's LDL-C to a different LDL-C treatment goal, which would potentially result in more drug usage, thus exposing patients to more potential adverse effects and at a much greater cost with little evidence of benefit.
BACKGROUND: Low-density lipoprotein cholesterol (LDL-C) has been clearly associated with the risk of developing coronary heart disease. The best and most convenient method for determining LDL-C has come under increased scrutiny in recent years. We present comparisons of the Friedewald calculated LDL-C (C-LDL-C) and direct LDL-C (D-LDL-C) using 3 different homogenous assays. This highlights differences between the 2 methods of LDL-C measurement and how this affects the classification of samples into different LDL-C treatment goals as determined by the National Cholesterol Education Program Adult Treatment Panel III guidelines thus potentially affecting treatment strategies. METHODS:Lipid profiles of a total of 2208 clinic patients were retrieved from the Central Arkansas VA Healthcare System clinical laboratory database. Samples studied were of 1-week period during the 3 periods studied: 2000 (period 1), 2002 (period 2), and 2005 (period 3). Different homogenous assays for D-LDL-C measurement were used for each of the 3 periods. RESULTS: There is a fundamental disagreement between D-LDL-C and C-LDL-C, although Pearson correlation coefficients are 0.93, 0.97, and 0.98 for periods 1, 2, and 3, respectively. Using the model for period 1, when C-LDL-C is 70 mg/dL, the predicted D-LDL-C is 95 mg/dL (36% higher). The differences between C-LDL-C and predicted D-LDL-C progressively decrease at higher LDL-C cut points. In the assay used in period 3, there are 290 samples with D-LDL-C values between 100 and 130 mg/dL. Of these, only 182 samples show agreement with C-LDL-C values, whereas 90 samples with a D-LDL-C in the 100- to 130-mg/dL range are in the 70- to 100-mg/dL range using the C-LDL-C assay. Although the κ statistics suggests the LDL-C measures have relatively high levels of agreement, the significant generalized McNemar tests (P < 0.01) provide additional evidence of disagreement between C-LDL-C and D-LDL-C during all the 3 periods. CONCLUSIONS: Our results highlight D-LDL-C measurements using 3 different assays during 3 different periods. In all assays, there is a substantial lack of agreement between D-LDL-C and C-LDL-C, which, in most cases, resulted in higher D-LDL-C values than C-LDL-C. This leads to clinically significant misclassification of patient's LDL-C to a different LDL-C treatment goal, which would potentially result in more drug usage, thus exposing patients to more potential adverse effects and at a much greater cost with little evidence of benefit.
Authors: F M Sacks; A M Tonkin; J Shepherd; E Braunwald; S Cobbe; C M Hawkins; A Keech; C Packard; J Simes; R Byington; C D Furberg Journal: Circulation Date: 2000-10-17 Impact factor: 29.690
Authors: James A de Lemos; Michael A Blazing; Stephen D Wiviott; Eldrin F Lewis; Keith A A Fox; Harvey D White; Jean-Lucien Rouleau; Terje R Pedersen; Laura H Gardner; Robin Mukherjee; Karen E Ramsey; Joanne Palmisano; David W Bilheimer; Marc A Pfeffer; Robert M Califf; Eugene Braunwald Journal: JAMA Date: 2004-08-30 Impact factor: 56.272
Authors: Christopher P Cannon; Eugene Braunwald; Carolyn H McCabe; Daniel J Rader; Jean L Rouleau; Rene Belder; Steven V Joyal; Karen A Hill; Marc A Pfeffer; Allan M Skene Journal: N Engl J Med Date: 2004-03-08 Impact factor: 91.245
Authors: F M Sacks; M A Pfeffer; L Moye'; L E Brown; P Hamm; T G Cole; C M Hawkins; E Braunwald Journal: Am J Cardiol Date: 1991-12-01 Impact factor: 2.778
Authors: Marcelo Jose Andrade Oliveira; Hendrick E van Deventer; Lorin M Bachmann; G Russell Warnick; Katsuyuki Nakajima; Masakasu Nakamura; Ikunosuke Sakurabayashi; Mary M Kimberly; Robert D Shamburek; William J Korzun; Gary L Myers; W Greg Miller; Alan T Remaley Journal: Clin Chim Acta Date: 2013-04-27 Impact factor: 3.786
Authors: Samia Mora; Michael P Caulfield; Jay Wohlgemuth; Zhihong Chen; H Robert Superko; Charles M Rowland; Robert J Glynn; Paul M Ridker; Ronald M Krauss Journal: Circulation Date: 2015-09-25 Impact factor: 29.690
Authors: Federica Piani; Isabella Melena; Kalie L Tommerdahl; Natalie Nokoff; Robert G Nelson; Meda E Pavkov; Daniël H van Raalte; David Z Cherney; Richard J Johnson; Kristen J Nadeau; Petter Bjornstad Journal: J Diabetes Complications Date: 2020-12-31 Impact factor: 2.852